Antimalarial Activity of Phenazines from Lapachol, Beta-lapachone and Its Derivatives Against Plasmodium Falciparum in Vitro and Plasmodium Berghei in Vivo

Overview

Journal Bioorg Med Chem Lett

Specialty Biochemistry

Date 2004 Feb 26

PMID 14980653

Citations 38

Authors

Valter F de Andrade-Neto

Marilia O F Goulart

Jorge F da Silva Filho

Matuzalem J da Silva

Maria do Carmo F R Pinto

Antonio V Pinto

Mariano G Zalis

Luzia H Carvalho

Antoniana U Krettli

Affiliations

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Abstract

The antimalarial activity of benzo[a]phenazines synthesized from 1,2-naphthoquinone, lapachol, beta-lapachone and several derivatives have been tested against Plasmodium falciparum in vitro using isolates of parasites with various susceptibilities to chloroquine and/or mefloquine. Parasite growth in the presence of the test drugs was measured by incorporation of [(3)H]-hipoxanthine in comparison to controls with no drugs, always testing in parallel chloroquine, a standard antimalarial. Among seven benzophenazines tested, four had significant in vitro activities; important, the parasites resistant to chloroquine were more susceptible to the active phenazines in vitro. The doses of phenazines causing 50% inhibition of parasite growth varied from 1.67 to 9.44 microM. The two most active ones were also tested in vivo against Plasmodium berghei in mice, in parallel with lapachol and beta-lapachone. The 3-sulfonic acid-beta-lapachone-derived phenazine was the most active causing up to 98% inhibition of parasitaemia in long term treatment (7 doses) subcutaneously, whereas the phenazine from 3-bromo-beta-lapachone was inactive. Thus, these simple phenazines, containing polar (-Br,-I) and ionizable (-SO(3)H, -OH) groups, easily synthesized from cheap, natural or synthetic precursors (lapachol and beta-lapachone), at rather low cost, provide prototypes for development of new antimalarials aiming the chloroquine resistant parasites.

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